JP2549935B2 - Signal processor - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a signal processing device for processing a received signal such as a pulse compression radar using a frequency modulation method.

[Prior Art] As a conventional signal processing device for processing a pulse having a long duration, there is one described in Japanese Patent Publication No. 56-20509 shown in FIG.

FIG. 3 is a block diagram showing the processing of the received signal in the above conventional example. In FIG. 3, (16) is a distributor for distributing the intermediate frequency signal, and (11) is a chirp delay for compression on the time axis. A line, (12) is a fixed variable delay line that gives a predetermined delay time for each section (channel) of a predetermined frequency and concentrates the signals of each channel at the same time, and (13) corrects the phase difference between the channels. A phase shifter, (14) an adder for adding signals, and (15) a detector for converting an intermediate frequency signal to a low frequency signal.

Next, the operation will be described. The intermediate frequency signal (FIG. 6a) converted from the received signal is distributed to the chirp delay lines (11a) and (11b) for each channel by the distributor (16) (S ₁ , S in FIG. 6b). ₂ ), each is compressed on the time axis. The chirp delay lines (11a) and (11b) have the characteristic that the delay time increases linearly with the increase in frequency as shown in FIG. 5a.

Fig. 4 shows an example of this type of delay line using surface acoustic waves, "Radar Technology", edited by ELI Brookner, Art.
It is quoted from ech Publishing Co., published in 1977, pp.171-174. The surface acoustic wave element (1) is provided on the piezoelectric body (2),
An input side interdigital transducer (3) for converting an electric signal into a surface acoustic wave and an output side interdigital transducer (4) for converting the surface acoustic wave into an electric signal again are provided. (5) is an electric signal lead wire. The output side interdigital transducer (4) is
The arrangement pitch of the electrode fingers is gradually changed linearly. In the area where the arrangement pitch is narrow, high-frequency surface acoustic waves are efficiently converted into electric signals. Conversely, where the array pitch is wide, the low frequency elastic surface is efficiently converted into an electrical signal. As shown in FIG. 4, the narrower array pitch is closer to the input interdigital transducer (3),
Since the wider the arrangement pitch is, the longer the arrangement pitch is, the characteristic that the delay time changes linearly with respect to the frequency change can be obtained.

The received signal compressed by the chirp delay line (11) is passed through the fixed variable delay lines (12a) and (12b) because the delay time is different for each channel as shown in FIG. By delaying by the amount corresponding to time, all signal components are concentrated at the same time. For this signal, the phase shifters (13a) and (13b) correct the phase difference between each channel, and the main lobe of the pulse compression waveform matches the peak value of the waveform compressed by a single chirp delay line. Adjust to When these signals are added by the adder (14), a compressed pulse as shown in FIG. 6c is obtained. The total delay characteristic at this time is the characteristic shown in FIG. 5b, and the amplitude of the compressed pulse after addition is the number of channels times the amplitude of each channel (double in FIG. 5). The output signal of the adder (14) is detected by the detector (15) and sent to the indicator for display.

Since this type of conventional signal processing device performs addition processing in the intermediate frequency band, it is essential to adjust the phase between the channels in the phase shifter (13). That is,
The chirp delay line (11) of each channel is designed to have the same characteristics, but the delay time is not the same due to the temperature characteristics and the length of the line, and the fixed variable delay line (12)
The output of will be out of phase for each channel. For example, when using lithium niobate (LiNbO ₃ ) for the delay line substrate, the change in characteristics with temperature is about 70 ppm / ° C.
When the pulse width is 10 μs, it changes by 0.7 ns per degree. Therefore, when the temperature changes by 10 degrees, the delay time changes by 7 ns.

In such a case, the intermediate frequency is usually a number + MHz
Therefore, even if the difference in delay time is about several nanoseconds,
A phase difference of tens of degrees occurs. If the phases do not match, the added amplitude will not be the number of channels multiplied. In order to avoid such a situation, the phase is adjusted and matched by the phase shifter (13), and the temperature change is reduced so that the phase shifter is used.

[Problems to be Solved by the Invention] However, the above-described phase adjustment requires a very high accuracy of about several nanoseconds, and the adjustment takes time,
There is a problem that the pulse compression cannot be performed correctly due to the change in the characteristics due to the temperature change after the adjustment, and the compression characteristics change.

[Means for Solving the Problems] Compression processing is performed for each preset frequency section,
A signal processing device for synthesizing processed signals is provided with a detector for detecting a signal for each of the sections, and synthesizes the detected signals.

[Operation] The signal processing device according to the present invention,
Performs compression processing for each preset frequency section,
Each of them is detected and then synthesized.

[Embodiment of the Invention] An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is a diagram for explaining the principle of the present invention. The case where the number of channels is 2 (N is 2) will be described as an example. The transmission pulse is frequency-modulated as shown in FIG. 1 (a), and the frequency changes from f ₀ to f ₀ + Δ as shown in FIG. 1 (b).
A pulse having a duration T that changes linearly up to f is transmitted.

On the other hand, the received pulse reflected from the target is frequency-converted by the frequency converter 6 to obtain the pulse shown in FIG. 1 (d) which has been subjected to the frequency modulation shown in FIG. 1 (c). That is, a duration T, 2f ₀ +2 frequency from 2f ₀
Modulation is performed so as to change linearly up to Δf. To compress a pulse of the first view (d) are, as shown in FIG. 1 (e), the delay time in the frequency 2f ₀ is T, the frequency is 2f ₀ +
At 2Δf, the delay time is zero, and at frequencies in between,
For the frequency conversion, a circuit in which the delay time changes linearly is necessary (in the conventional example, this characteristic is opposite, but in the conventional example, for a signal whose characteristic is inverted by the spectrum inverter, It is for processing, and the operation of the compression processing is the same). In the present invention, the frequency vs. time characteristic shown in FIG.
It is realized by a combination of frequency vs. delay time characteristics shown in (g) and (h). In the characteristic shown in FIG. 1 (f), the delay time is constant as T / 2 at frequencies between 2f ₀ and 2f ₀ + Δf. In the characteristics shown in FIG. 1 (g), while the frequency changes from 2f ₀ to 2f ₀ + Δf, the delay time varies linearly from T / 2 to zero. The characteristic of FIG. 1 (h), while the frequency changes from 2f ₀ + Delta] f to 2f ₀ + 2Δf, delay time varies linearly from T / 2 to zero. Therefore, it will be easily understood from the figure that the characteristics shown in FIG. 1 (e) can be obtained by adding the three characteristics shown in FIGS. 1 (f), (g) and (h).

1 (f), (g), and (h), only the frequency characteristic of the delay time is shown, but the frequency characteristic of the passing power is 2f in FIG. 1 (f) and (g). ₀ to 2f ₀ +
The passing power level is set to be high only up to Δf, and the normal power level is set to be low at other frequencies. In FIG. 1 (h), frequencies 2f ₀ + Δf to 2f ₀
The passing power level is set to be large only up to + 2Δf, and the passing power level is set to be small at other frequencies.

Now, the pulse shown in FIG. 1 (d) is changed to the pulse shown in FIG. 1 (f).
After passing through a circuit having the characteristics shown in Fig. 1, after that, see Fig. 1 (g).
Pass through a circuit having the characteristics shown in. These circuits respond strongly only during the first T / 2 interval of pulse duration T. This is because the frequency changes from 2f ₀ to 2f ₀ + Δf in the first T / 2 section, and as described above, the pass power level is large in this frequency band, and in the second half T / 2 section, the frequency Is changing from 2f ₀ + Δf to 2f ₀ + 2Δf, and the passing power level is small in this frequency band.

Therefore, after passing through the circuit having the characteristic shown in FIG. 1 (f), a pulse obtained by only delaying the first T / 2 section by T / 2 is obtained. After passing through the circuit having the characteristic shown in FIG. 1 (g), the compressed pulse shown in FIG. 1 (i) is obtained. Here, the width of the main lobe of the compressed pulse is 1 / Δf. This is because, in the first T / 2 intervals, because the frequency is changed by Delta] f and the 2f ₀ to 2f ₀ + Δf.

On the other hand, the pulse shown in FIG. 1 (d) is separately passed through a circuit having the characteristics shown in FIG. 1 (h). This circuit is
It responds strongly only in the second half of the pulse duration T, that is, in the section of T / 2. Because the frequency is 2f _{0 in} the latter half of T / 2.
Since changes from + Delta] f to 2f ₀ + 2.DELTA.f, large passing power level in this frequency band, the first half of the T / 2 of the interval, the frequency is changed from 2f ₀ to 2f ₀ + Delta] f, in the frequency band , Because the passing power level is small. After passing through the circuit having the characteristic shown in FIG. 1 (h), the compressed pulse shown in FIG. 1 (j) is obtained. Here, the width of the main lobe of the compressed pulse is 1 / Δf.
Because, in the latter half of T / 2, the frequency is 2f ₀ + Δf
This is because there is a change of from Δf to 2f ₀ + 2Δf by Δf.

Therefore, the compressed pulse shown in FIGS. 1 (i) and (j) is
After envelope detection and conversion from the intermediate frequency band to the base band, these are added, as shown in FIG. 1 (k),
A compressed pulse with a main lobe width of 1 / Δf can be obtained. In this processing method, since the baseband signals lower than the intermediate frequency (about 1/10) are converted and added as described above, even if there is a delay time difference of several nS between channels, the phase difference caused by the delay time is It is slight, and the signals of the respective channels can be accumulated by simply adding without adjusting the phase. This eliminates the need for delicate adjustment, which is extremely difficult to adjust the phase, and saves the trouble of adjustment. Also, temperature changes,
Even if there is a phase difference due to aging or the like, deterioration of the characteristics is small.

FIG. 2 is an example of a configuration in which the signal processing process shown in FIG. 1 is specifically configured using the surface acoustic wave element (1). When the pulse received from the target is passed through the frequency converter (6), the pulse shown in FIG. 1 (d) is obtained. This signal is branched into two, one of which is passed through a surface acoustic wave element (1a) having the characteristics shown in FIG. 1 (f), and further the surface acoustic wave element having the characteristics passed in FIG. 1 (g). (1b)
, The compressed pulse shown in FIG. 1 (i) is obtained. On the other hand, if one of the previously branched pulses is passed through the surface acoustic wave device (1c) having the characteristic shown in FIG. 1 (h), the compressed pulse shown in FIG. 1 (j) is obtained. . The two compressed pulses thus obtained are respectively passed through a detector (7) for envelope detection and then combined by a combiner (8) to obtain the desired signal shown in FIG. 1 (k). Compressed pulses can be obtained.

In the above, the case of N = 2 is shown as an example, but the present invention is not limited to this, and can similarly be extended and applied to the case of N = 3 or more. Note that N =
It is easy to extend the signal processing process shown in FIG. 1 and the circuit configuration shown in FIG. Although the case where the pulse whose frequency changes linearly with respect to time is used has been described, the present invention may be applied to the case where the pulse whose frequency changes nonlinearly with respect to time is used. Absent.

[Effects of the Invention] The compression process is performed for each preset frequency interval,
In the signal processing device for synthesizing, each is provided with a detector that detects the signal of each section, and by synthesizing after detecting the compressed signals respectively, the configuration is simple without the need for a phaser for adjusting the phase. Therefore, it is not necessary to adjust the phase difference between the phase shifters, which is difficult.
Adjustment becomes easy and stable operation becomes possible.

[Brief description of drawings]

FIG. 1 is an explanatory view showing the principle of an embodiment of the present invention, FIG. 2 is a block diagram showing an embodiment of a signal processing device based on the principle of FIG. 1, and FIG. FIG. 4 is a pattern diagram showing an example of the configuration of a surface acoustic wave element, FIG. 5 is an explanatory view showing the principle of a conventional signal processing device, and FIG. 6 is a conventional diagram. FIG. 6 is a diagram for explaining a pulse compression operation of the signal processing device of FIG. In the figure, (1) is a surface acoustic wave element, (2) is a piezoelectric substrate,
(3) is an input-sided power pole, (4) is an output-sided power pole, (5) is a lead wire, (6) is a frequency converter,
(7) is a detector and (8) is a combiner. In the drawings, the same or corresponding parts are designated by the same reference numerals.

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Tsutomu Nagatsuka 5-1-1, Ofuna, Kamakura-shi, Kanagawa Sanryo Electric Co., Ltd. Information Electronics Laboratory (56) References Japanese Patent Publication Sho 56-20509 (JP, B2)

Claims (1)

(57) [Claims] 1. A signal processing device for performing pulse compression processing on a frequency-modulated pulse reception signal, wherein the frequency of the pulse reception signal having a duration T changing from f0 to f0 + Δf is defined as an integer N. From Nf0 to Nf0 + N
Frequency conversion means for performing frequency conversion into a pulse having a duration T that changes to Δf, and a first delay for performing a time delay corresponding to each section with respect to the output of the frequency conversion means for each section of a preset frequency. Means, and second delay means for respectively performing a time delay corresponding to the frequency in each section for each output of the first delay means, and for the output of the frequency conversion means, among the sections of the frequency A third delay means for performing a time delay corresponding to the frequency of a predetermined part of the section, a detector for detecting the output of the second delay means and the output of the third delay means, respectively, A signal processing device comprising: a combiner that combines the outputs of the detectors.